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I have two sorted lists of integers. I would like to find all pairs of integers from the first and second list, respectively, that are within a certain distance of each other.

The naive approach is to check each pair, resulting in a O(N^2) time. I am sure there is a way to do it in O(N*logN) or maybe shorter.

In python, the naive O(N^2) approach is as follows:

def find_items_within(list1, list2, within):
    for l1 in list1:
        for l2 in list2:
            if abs(l1 - l2) <= within:
                yield (l1, l2)

Extra points for pythonic answers.

Application Note

I just wanted to point out the purpose of this little puzzle. I am searching a document and want to find all the occurrences of one term within a certain distance of another term. First you find the term vectors of both terms, then you can use the algorithms described below to figure out if they are within a given distance of each other.

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7 Answers 7

up vote 3 down vote accepted

This code is O(n*log(n)+m) where m is the size of the answer.

def find_items_within(l1, l2, dist):
    l1.sort()
    l2.sort()
    b = 0
    e = 0
    ans = []
    for a in l1:
        while b < len(l2) and a - l2[b] > dist:
            b += 1
        while e < len(l2) and l2[e] - a <= dist:
            e += 1
        ans.extend([(a,x) for x in l2[b:e]])
    return ans

In the worst case, it is possible that m = n*n, but if the answer is just a small subset of all possible pairs, this is a lot faster.

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Lots of good suggestions here, but I think this one is the easiest to understand, does not rely on anything too fancy and has algorithmic time as good or better than the others. Although @J.F. Sebastian's answer claims to be faster, I think it's the same when you factor in the O(log(n)) lookups it does. –  speedplane Nov 30 '12 at 2:47
    
@speedplane: set() in Python has O(1) amortized lookups as the comments in my code explicitly say (think unordered_set<> in C++, not set<> with O(log(n))). btw, the time complexity is not better it is the same if .sort() is removed above (my answer assumes that the input is sorted as said in the first sentence of your question and assert issorted() statements in the code hint about it too). This answer is 2-3 times faster for the input I've tried on my machine. –  J.F. Sebastian Nov 30 '12 at 19:07
    
@speedplane: btw, Thomash's answer can be made linear time if ans.extend is replaced with yield i, (b,e) where l1[i] == a. You will still need O(n*n) to enumerate all pairs explicitly, but you can find pairs (as in: know their indexes range) in O(n) for sorted input. –  J.F. Sebastian Nov 30 '12 at 19:12
    
@J.F.Sebastian: It is not possible to have a linear time algorithm because the output is not linear. The best you can do is O(m) where m is the size of the output and that is the complexity of my algorithm if you consider the input to be sorted. –  Thomash Nov 30 '12 at 20:20
    
@Thomash: have you read "You will still need O(n*n) (O(m) using your terminology) to enumerate all pairs explicitly" part of my comment? A single yield i, (b, e) gives you e-b pairs at once. –  J.F. Sebastian Nov 30 '12 at 20:30

There is no way to do it better then O(n^2) because there are O(n^2) pairs, and for within = infinity you need to yield all of them.


To find the number of these pairs is a different story, and can be done by finding the first index for each element e that suffices within-e < arr[idx]. The index idx can be found efficiently using binary search for example - which will get you O(nlogn) solution to find the number of these pairs.

It can also be done in linear time (O(n)), since you don't really need to do a binary search for all elements, after the first [a,b] range is found, note that for each other range [a',b'] - if a>a' then b>=b' - so you actually need to iterate the lists with two pointers and "never look back" to get a linear time complexity.

pseudo code: (for linear time solution)

numPairs <- 0
i <- 0
a <- 0
b <- 0
while (i < list1.length):
  while (a < i && list1[i] - list2[a] > within):
      a <- a+1
  while (b < list2.length && list2[b] - list1[i] < within):
      b <- b+1
  if (b > a):
      numPairs <- numPairs + (b-a)
  i <- i+1
return numPairs

(I made some fixes from the initial pseudo code - because the first one was aiming to find number of pairs within range in a single list - and not matches between two lists, sorry for that)

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(and for binary search - the OP should look at the bisect module) –  Jon Clements Nov 29 '12 at 14:20
    
I think number of pairs can be done in O(n) - just find the window for the first number, and slide it for subsequent numbers. –  nhahtdh Nov 29 '12 at 14:21
1  
amit -- You don't need to test them all. since the data is sorted, once you get outside the distance you care about, you can safely break that loop. –  mgilson Nov 29 '12 at 14:22
1  
@mgilson: No need for the numbers to be equally spaced. The window can grow and shrink. –  nhahtdh Nov 29 '12 at 14:24
1  
@mgilson: Yes, but the 2 pointers will slide exactly n times. We just start from the previous position. –  nhahtdh Nov 29 '12 at 14:39

Here something with the same interface as you have given:

def find_items_within(list1, list2, within):
    i2_idx = 0
    shared = []
    for i1 in list1:
        # pop values to small
        while shared and abs(shared[0] - i1) > within: 
            shared.pop(0)
        # insert new values 
        while i2_idx < len(list2) and abs(list2[i2_idx] - i1) <= within:
            shared.append(list2[i2_idx])
            i2_idx += 1
        # return result
        for result in zip([i1] * len(shared), shared):
            yield result

for item in find_items_within([1,2,3,4,5,6], [3,4,5,6,7], 2):
    print item

Not very beautiful but it should do the trick in O(N*M), where N is the length of list1 and M the list of shared pairs per Item (given that the elements dropped and appended to shared is constant on the average).

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Depending on the distribution of the values in your lists, you might be able to speed things up by using binning: take the range in which all your values fall (min(A+B), max(A+B)), and divide that range into bins of the same size as the distance D you’re considering. Then, to find all pairs, you only need to compare values within a bin or within adjacent bins. If your values are split up between many bins, this is an easy way to avoid doing M*N comparisons.

Another technique that might be just as easy in practice: Do a sort of bounded linear scan. Maintain an index into list A and into list B, starting from the beginning. On each iteration, advance the index into list A (start with the first element), call this element A0. Then, advance the index into list B. Remember the last value of B that’s less than A0-D (this is where we’ll want to start for the next iteration). But keep moving forward while you’re finding values between A0-D and A0+D — these are the pairs you’re looking for. As soon as the values in B become greater than A0+D, stop this iteration and start the next one — advance one element further into A, and start scanning B from the last place where B was < A0-D.

If you have, on average, a constant number of nearby pairs per element, I think this should be O(M+N)?

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This method uses a dictionary whose keys are possible values of list2, and whose values are a list of values of list1 that are within distance of that value of list2.

def find_items_within(list1, list2, within):
    a = {}
    for l1 in list1:
        for i in range(l1-within, l1+within+1):
            if i not in a:
                a[i] = []
            a[i].append(l1)
    for l2 in list2:
        if l2 in a:
            for l1 in a[l2]:
                yield(l1, l2)

The complexity for this one is kind of goofy. for a list1 of size M and a list2 of size N and a within of size W, it's O(log(M*W) * (M*W + N)). In practice I think it works pretty well for small W.

Bonus: this works on unsorted lists too.

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Nice approach using dictionaries. The downside however is that it also allocates a structure of M*W size. –  speedplane Nov 29 '12 at 16:12

This seems to work:

from itertools import takewhile
def myslice(lst,start,stop,stride=1):
    stop = len(lst) if stop is None else stop
    for i in xrange(start,stop,stride):
        yield lst[i]

def find_items_within(lst1,lst2,within):
    l2_start = 0
    for l1 in lst1:
        try:
            l2_start,l2 = next( (i,x) for i,x in enumerate(myslice(lst2,l2_start,None),l2_start) if abs(l1-x) <= within )
            yield l1,l2
            for l2 in takewhile(lambda x:(abs(l1-x) <= within), myslice(lst2,l2_start+1,None)):
                yield l1,l2
        except StopIteration:
            pass


x = range(10)
y = range(10)
print list(find_items_within(x,y,2.5))
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You can find integers from list2 that are in [x - within, x + within] interval for all x from list1 in linear time (O(n)) using "scan line" technique (see How to Find All Overlapping Intervals and Sub O(n^2) algorithm for counting nested intervals?).

To enumerate corresponding intervals from list1 you need O(m) time where m is the number of intervals i.e., the overall algorithm is O(n*m):

from collections import namedtuple
from heapq import merge

def find_items_within(list1, list2, within):
    issorted = lambda L: all(x <= y for x, y in zip(L, L[1:]))
    assert issorted(list1) and issorted(list2) and within >= 0

    # get sorted endpoints - O(n) (due to list1, list2 are sorted)
    Event = namedtuple('Event', "endpoint x type")
    def get_events(lst, delta, type):
        return (Event(x + delta, x, type) for x in lst)
    START, POINT, END = 0, 1, 2 
    events = merge(get_events(list1, delta=-within, type=START),
                   get_events(list1, delta=within, type=END),
                   get_events(list2, delta=0, type=POINT))

    # O(n * m), m - number of points in `list1` that are 
    #               within distance from given point in `list2`
    started = set() # started intervals
    for e in events:  # O(n)
        if e.type is START: # started interval
            started.add(e.x) # O(m) is worst case (O(1) amortized)
        elif e.type is END: # ended interval
            started.remove(e.x)  # O(m) is worst case (O(1) amortized)
        else:  # found point
            assert e.type is POINT
            for x in started:  # O(m)
                yield x, e.x

To allow duplicate values in list1; you could add index for each x in Event and use a dictionary index -> x instead of the started set.

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